The anterior pituitary of the Japanese quail,Coturnix coturnix japonica

Summary The cytology of the adenohypophysis of the male Japanese quail (Coturnix coturnix japonica) has been studied under a variety of experimental conditions: (1) treatment with long daily photoperiods for variable lengths of time; (2) the change from a long to a short daily photoperiod which induces gonadal regression; (3) castration followed by exposure to either short or long daily photoperiods, and (4) treatment with thyroxine, thiourea and metapirone. In parallel with the Cytological investigations, information on the level of hypophysial gonadotropins has been obtained by bioassay.The cytological investigations permit the recognition of seven types of cells in the adenohypophysis and the identification of gonadotropic cells, thyrotropic cells, and corticotropic cells. The significance of the orangeophilic alpha (STH ?) cells, and the erythrosinophilic eta (prolactin ?) cells remains hypothetical. A seventh cell type kappa is hypercyanophilic and positive with lead hematoxylin; it has been identified in other species of birds and may be a melanophorotropic cell.In castrates, an increase in pituitary gonadotropin appears only with photostimulation. It appears that photostimulation increases thyrotropic activity, an effect that is enhanced by castration.This investigation was supported by Grant No. 5 ROI NB 06,187 from the National Institute of Neurological Diseases and Blindness and by an allocation from the Graduate School Research Fund to Professor Farner.Part of the study was aided by an A. R. C. grant (AG. 24/36) to Dr. B. K. Follett.We are grateful to Doctor August Epple for his histologie analysis of some of the target glands.We wish to thank Miss Maryvonne Lefalchier, biologiste-adjointe du C. N. R. S. for excellent technical assistance in the cytological preparation of the pituitaries.     

Perifusion model system to culture bovine hypothalamic slices in series with dispersed anterior pituitary cells

Summary Dispersed bovine anterior pituitary cells were incubated either in static or perifusion cultures to assess basal growth hormone release as well as stimulatory and inhibitory effects of growth hormone-releasing hormone and somatostatin, respectively, on growth hormone release. Total concentrations of growth hormones over a 12-hour incubation period were fivefold greater in perifused than in static cultures (2034 ± 160 vs. 387 ± 33 ng/12 h). A dose-dependent increase in growth hormone secretion in response to challenge with growth hormone-releasing hormone (10⁻¹² to 10⁻⁸ M) for 1 h was observed in both static and perifusion cultures; however, perifused cells were more responsive to the same concentration of neuropeptide than those in static culture. Concentrations of somatostatin (10⁻¹² to 10⁻⁸ M) for 1 h did not inhibit basal growth hormone secretion in either static or perifusion cultures. To establish model, slices of the hypothalamus, immediately adjacent to the sagittal midline, were perifused in series with anterior pituitary cells, and media effluent was assayed for growth hormone concentrations. Release of growth hormone was pulsatile and seemed to mimic the episodic pattern of bovine secretion. Hypothalamic slices were placed in one chamber of the perifusion system, and basal secretion of growth hormone-releasing hormone and somatostatin was pulsatile in media effluent. Tissue viability of hypothalamic slices and anterior pituitary cells was evaluated by KCl depolarization. Tissues were viable for at least 120 h. Thus, this hypothalamo-pituitary dual chamber perifusion system is a valid in vitro model to study regulation of growth hormone secretion.     

Immunocytochemical markers revealing retinal and pineal but not hypothalamic photoreceptor systems in the Japanese quail

Summary The retinal proteins opsin,-transducin, S-antigen and interstitial retinol-binding protein (IRBP) are essential for the processes of vision. By use of immunocyto-chemistry we have employed antibodies directed against these photoreceptor proteins in an attempt to identify the photoreceptor systems (retina, pineal and deep brain) of the Japanese quail. Opsin immunostaining was identified within many outer (basal portion) and inner segments of retinal photoreceptor cells and limited numbers of photoreceptor perikarya. Opsin immunostaining was also demonstrated in limited numbers of pinealocytes with all parts of these cells being immunoreactive. These results differ from previous observations. In contrast to the results obtained with the antibody against opsin, S-antigen and-transducin immunostaining was seen throughout the entire outer segments and many photoreceptor perikarya of the retina. In the pineal organ immunostaining was seen in numerous pinealocytes in all follicles. These results conform to previous findings in birds. In addition, IRBP has been demonstrated for the first time in the avian retina and pineal organ. These findings underline the structural and functional similarities between the retina and pineal organ and provide additional support for a photoreceptive role of the avian pineal. No specific staining was detected in any other region of the brain in the Japanese quail; the hypothalamic photoreceptors of birds remain unidentified.     

Pineal and hypothalamic pacemakers: Their role in regulating circadian rhythmicity in Japanese quail

Summary Neither pinealectomy nor administration of melatoninvia silastic capsules had any effect on free-running circadian rhythms of locomotor activity in Japanese quail (Coturnix coturnix japonica). The quail, like the chicken, therefore differs from sparrows and starlings in which pinealectomy dramatically disrupts free-running rhythms. Nevertheless, it seems unlikely that there are fundamental differences in circadian organisation within the Class Aves. The effects of lesions within the supraoptic region (SOR) of the hypothalamus were similar to those which follow the ablation of the suprachiasmatic nuclei (SCN) in sparrows, rats and hamsters, causing the breakdown of free-running rhythms of locomotor activity, but not necessarily an arrhythmic state. The SOR and SCN appear then to have homologous functions in birds and mammals. Differences in circadian organisation, such as the degree of influence of the pineal gland and the particular photoreceptors used for entrainment, may therefore be modifications peripheral to the fundamental components of the circadian clock.Abbreviations POR preoptic area - SOR supraoptic region - SCN suprachiasmatic nuclei     

Tanycyte absorption affected by the hypothalamic deafferentation in Japanese quail,Coturnix coturnix japonica

In Japanese quail, Coturnix coturnix japonica the tanycytes of the median eminence absorbed peroxidase injected into the third ventricle. The number of tanycytes showing peroxidase reaction was greater in the posterior median eminence than in the anterior median eminence. Following hypothalamic deafferentation, the tanycyte absorption was augmented both in the posterior and anterior median eminence. These findings suggest that axons of some neurons, which have inhibitory action on the tanycyte absorption, were transected by deafferentation resulting in augmentation of tanycyte absorption. A considerable number of ependymal cells lining the upper portion of the third ventricle and those of the pars nervosa also absorbed peroxidase. In birds with a deafferented hypothalamus, photostimulated ovarian growth was completely inhibited.     

Changes in pituitary responsiveness during the ovulatory cycle of the Japanese quail, in vitro

Anterior pituitary glands from ovulating Japanese quail (Coturnix coturnix) were used to investigate variation in sensitivity to chicken luteinizing hormone-releasing hormone (cLHRH I; Gln8-LHRH). Grouping the pituitaries by ovulatory stage provided preliminary evidence of changes in sensitivity to LHRH during the ovulatory cycle. Pituitaries taken from quail before the preovulatory LH surge were responsive to cLHRH I, while pituitaries from the other times of the cycle showed minimal response to cLHRH I. Female pituitary glands release less LH than those of males. These data indicate a change in sensitivity to LHRH in the female quail that may be due to changes in gonadal steroids or the pool of releaseable LH from the pituitary.     

Lateral hypothalamic neuropeptides in reward and drug addiction

The hypothalamus has been long considered important in feeding and other motivated behaviors. The identification of neuropeptides expressed in the hypothalamus has initiated efforts to better elucidate the underlying molecular mechanisms involved. The neuropeptides orexin and melanin-concentrating hormone (MCH) are expressed in the lateral hypothalamus (LH) and have been implicated in regulation of feeding behavior. Neurons expressing these neuropeptides have extensive projections to regions of the brain important for behavioral responses to drugs of abuse, raising the possibility that the pathways may also be important in addiction. Regulation of LH intracellular signaling pathways in response to drugs of abuse supports a role for the LH neuropeptides in addiction.     

Induction of rapid testicular growth in Japanese quail by phasic electrical stimulation of the hypothalamic photosensitive area

Summary Optic fibers were implanted stereotaxically into the brain of immature male Japanese quail reared under short-day photoperiod (lights on from 1000 to 1800 h), and photosensitive sites in the hypothalamus were examined using gonadal growth and associated hormonal changes as the indices.In the subsequent experiments, bipolar (coaxial) electrodes were implanted chronically using predetermined coordinates for highly photosensitive sites. Henceforth the birds received brief electrical stimulation (square wave, 100 Hz, 100A, 2 min) once daily for 21 consecutive days. When the electrical stimulation was applied early in the dark period, marked gonadal growth was induced, but identical stimulation given in the light period resulted in no testicular growth. The response curve of testicular weight vs clock time of electrical stimulation has a prominent peak at 3 h after the onset of dark. Apparently, the neural complex in the photosensitive area of the quail hypothalamus responds to electrical stimulation as it does to light. We conclude that in photoperiodic birds the principal factor which determines the magnitude of gonadal responses is not the intensity of the stimulus but its timing (circadian phase).Abbreviations GnRH gonadotropin releasing hormone - LD light and dark - LED light emitting diode - CRT cathode ray tube - LH luteinizing hormone - OD outer diameter - ID inner diameter     

Smooth muscle cells in the walls of ovarian follicles in the Japanese quail

Summary The walls of pre-ovulatory follicles of the Japanese quail were examined at the ultrastructural level for the presence of cells displaying the typical morphological features of smooth muscle cells. These characteristics were found in the cells of the chordae, the tunica albuginea, and the theca externa. Small, elongated cells, containing microfilaments, were observed in the theca of prelampbrush follicles localized in the ovarian cortex. These thecal cells were considered as the putative precursors of the thecal smooth muscle cells of the pre-ovulatory follicle. The difference between the smooth muscle cells of the pre-ovulatory follicle and those in the wall of the most recent post-ovulatory follicle is the contracted state of the latter, which is most evident in the cells of the theca externa. It can be concluded that the cells of the theca externa are smooth muscle cells which are mainly contracted during the ovulatory process. A comparison was made with other vertebrate species.     

Localization of neuropeptide Y-immunoreactive cells and fibres in the brain of the Japanese quail

Summary In the present study, we have demonstrated, by means of the biotin-avidin method, the widespread distribution of neuropeptide Y (NPY)-immunoreactive structures throughout the whole brain of the Japanese quail (Coturnix coturnix japonica). The prosencephalic region contained the highest concentration of both NPY-containing fibres and perikarya. Immunoreactive fibres were observed throughout, particularly within the paraolfactory lobe, the lateral septum, the nucleus taeniae, the preoptic area, the periventricular hypothalamic regions, the tuberal complex, and the ventrolateral thalamus. NPY-immunoreactive cells were represented by: a) small scattered perikarya in the telencephalic portion (i.e. archistriatal, neostriatal and hyperstriatal regions, hippocampus, piriform cortex); b) medium-sized cell bodies located around the nucleus rotundus, ventrolateral, and lateral anterior thalamic nuclei; c) small clustered cells within the periventricular and medial preoptic nuclei. The brainstem showed a less diffuse innervation, although a dense network of immunopositive fibres was observed within the optic tectum, the periaqueductal region, and the Edinger-Westphal, linearis caudalis and raphes nuclei. Two populations of large NPY-containing perikarya were detected: one located in the isthmic region, the other at the boundaries of the pons with the medulla. The wide distribution of NPY-immunoreactive structures within regions that have been demonstrated to play a role in the control of vegetative, endocrine and sensory activities suggests that, in birds, this neuropeptide is involved in the regulation of several aspects of cerebral functions.Abbreviations AA archistriatum anterius - AC nucleus accumbens - AM nucleus anterior medialis - APP avian pancreatic polypeptide - CNS centrai nervous system - CO chiasma opticum - CP commissura posterior - CPi cortex piriformis - DIC differential interferential contrast - DLAl nucleus dorsolateralis anterior thalami, pars lateralis - DLAm nucleus dorsolateralis anterior thalami, pars medialis - E ectostriatum - EW nucleus of Edinger-Westphal - FLM fasciculus longitudinalis medialis - GCt substantia grisea centralis - GLv nucleus geniculatus lateralis, pars ventralis - HA hyperstriatum accessorium - Hp hippocampus - HPLC high performance liquid chromatography - HV hyperstriatum ventrale - IF nucleus infundibularis - IO nucleus isthmo-opticus - IP nucleus interpeduncularis - IR immunoreactive - LA nucleus lateralis anterior thalami - LC nucleus linearis caudalis - LFS lamina frontalis superior - LH lamina hyperstriatica - LHRH luteinizing hormone-releasing hormone - LoC locus coeruleus - LPO lobus paraolfactorius - ME eminentia mediana - N neostriatum - NC neostriatum caudale - NPY neuropeptide Y - NIII nervus oculomotorius - NV nervus trigeminus - NVI nervus facialis - NVIIIc nervus octavus, pars cochlearis - nIV nucleus nervi oculomotorii - nIX nucleus nervi glossopharyngei - nBOR nucleus opticus basalis (ectomamilaris) - nCPa nucleus commissurae pallii - nST nucleus striae terminalis - OM tractus occipitomesencephalicus - OS nucleus olivaris superior - PA palaeostriatum augmentatum - PBS phosphate-buffered saline - POA nucleus praeopticus anterior - POM nucleus praeopticus medialis - POP nucleus praeopticus periventricularis - PP pancreatic polypeptide - PYY polypeptide YY - PVN nucleus paraventricularis magnocellularis - PVO organum paraventriculare - R nucleus raphes - ROT nucleus rotundus - RP nucleus reticularis pontis caudalis - Rpc nucleus reticularis parvocellularis - RPgc nucleus reticularis pontis caudalis, pars gigantocellularis - RPO nucleus reticularis pontis oralis - SCd nucleus subcoeruleus dorsalis - SCv nucleus subcoeruleus ventralis - SCNm nucleus suprachiasmaticus, pars medialis - SCNl nucleus suprachiasmaticus, pars lateralis - SL nucleus septalis lateralis - SM nucleus septalis medialis - Ta nucleus tangentialis - TeO tectum opticum - Tn nucleus taeniae - TPc nucleus tegmenti pedunculo-pontinus, pars compacta - TSM tractus septo-mesencephalicus - TV nueleus tegmenti ventralis - VeL nucleus vestibularis lateralis - VLT nucleus ventrolateralis thalami - VMN nucleus ventromedialis hypothalami A preliminary report of this study was presented at the 15th Conference of European Comparative Endocrinologists, Leuven, Belgium, September 1990     

Magnesium deficiency in the Japanese quail

Morphological effects of magnesium deficiency on liver cells and general aspects of its influence on the metabolism were investigated in young quails. Magnesium deficiency was characterized by a depressed growth, a high mortality rate, a decrease in hematocrit and magnesium and calcium plasma concentrations. Magnesium deficiency reduced the magnesium concentration in heart by 44%, but did not affect the concentration in liver. Ultrastructural aspect of liver parenchymal cells revealed that the number of mitochondria per cell section was decreased and the average area of a mitochondrion was greater in deficient quails than in control animals. The significance of these morphological changes was discussed in relation to disturbances in energy metabolism of these organelles. From these results, japanese quail appeared as an interesting experimental model for studies on metabolic disturbances in magnesium deficiency.     

Nutrition and hypothalamic neuropeptides in sheep: histochemical studies

The identification and role of neuropeptides in the control of food intake and energy balance have been extensively studied in rodents, and for more than ten years, similar studies have been performed in sheep. As a photoperiodic ruminant, sheep are an interesting alternative animal model to rodents. In this review, we summarize the results obtained in sheep concerning the distribution of peptide-containing neurones in the hypothalamus and their central role in the control of food intake and energy balance, and compared them with relevant data from rodents. Even if the general organization and the role of hypothalamic neuropeptides are similar in sheep and rodents, numerous differences have been observed between these two species. In sheep, the magnocellular neurones of the paraventricular and supraoptic nuclei are characterized by the low density and the lack of galanin- and neuropeptide-Y-containing neurones, respectively. The sheep pituitary stalk presents neurones containing neuropeptides such as neuropeptide-Y or beta-endorphin, which are also found in the deep part of the infundibular nucleus. In this structure, several neuronal populations, including galanin, agouti-gene related peptide, somatostatin, are sensitive to energy balance variations, undernutrition or overfeeding, which may specifically modify neuropeptide levels in discrete neuronal subgroups. This feature is well illustrated by the number of neuropeptide-Y labelled neurones, that increases in the lateral part of the infundibular nucleus of undernourished ewes and decreases in the ventral part of overfed ewes. Conversely, after 24 hours of food deprivation, the number of neuropeptide-Y-immunolabelled neurones is unchanged in the sheep infundibular nucleus, whereas increased levels of this neuropeptide are described, in rats, by radioimmuno-assay. In conclusion, our review shows that peptide-containing neurone systems, involved in the regulation of food intake and energy balance in sheep, are generally similar to those observed in other species, but they present specific differences according to the physiological characteristics of the animal model.